Optical sheet, image source unit and image display device

ABSTRACT

A laminate includes: a substrate layer; and an optical function layer that is layered on one surface of the substrate layer, and has a plurality of light transmission parts which are arranged in a row along a surface of the substrate layer so as to be light-transmissive, and light absorption parts in a row, each of which is arranged between adjacent ones of the light transmission parts so as to be light-absorptive, wherein on a cross section of the optical function layer in the layer thickness direction, a cross-sectional area of one of the light transmission parts to the total cross-sectional area of one of the light transmission parts and one of the light absorption parts which are adjacent to each other is 78.2% to 88.5%, and optical diffuse reflectances thereof satisfy predetermined values.

TECHNICAL FIELD

The present invention relates to optical sheets that control lightemitted by light sources, to emit the light in observer sides, and imagesource units and image display devices that include the optical sheets.

BACKGROUND ART

Light sources and optical sheets are included in image display devicesthat emit images to observers, like liquid crystal displays, rearprojection display devices, display devices using organicelectroluminescence, and field emission displays (FEDs). Such an opticalsheet is composed of a plurality of layers that have various functionsfor improving the quality of light emitted by the light source to offerthe light to observers.

For example, such an optical sheet is disclosed in each of WO2010/148082and JP 2010-217871 A.

The optical sheet (light control film) of WO2010/148082 has transmissiveregions that are arranged in a row along a sheet surface so as to belight-transmissive, and absorptive regions that are arranged in a row,each of which is between transmissive regions, so as to belight-absorptive. It is disclosed that a width at the narrowest regionof a transmissive region and pitch of transmissive regions have acertain relationship.

The optical sheet of JP 2010-217871 A includes an optical functionalsheet layer that has prisms arranged in a row along a sheet surface soas to be light-transmissive, and light absorption parts arranged in arow, each of which is between prisms, so as to be light-absorptive.Thereby, an image light and outside light are reflected and absorbed, toimprove the quality of the image light.

Here, interference fringes and scintillation (so-called glare) aresometimes generated in such an optical sheet, originating from a mode ofarrangement of light absorption parts and light transmission partsalternately in a stripe pattern, light concentration due to control ofthe light, a mode of contact interfaces with other layers, etc. For thisgeneration, JP 2010-217871 A discloses that a surface of a base film isprepared to be a rough surface of no less than 0.1 μm in mean roughness(Ra), so that interference fringes can disappear.

SUMMARY OF INVENTION Technical Problem

Having such a light absorption part (absorptive region) makes itpossible to absorb light that causes something bad, at the lightabsorption part to have a proper light blocking effect. “Light blockingeffect” means performance in light control in a desired direction. Ahigh light blocking effect makes it possible to control light, not to beemitted in a predetermined direction. In contrast however, there is aproblem that efficiency of light utilization deteriorates because lightis absorbed. While the art as WO2010/148082 is disclosed, conventionalarts are not necessarily satisfying in view of having a light blockingeffect beyond a certain level and obtaining high efficiency of lightutilization.

Although the generation of interference fringes can be prevented byproviding a rough surface of no less than 0.1 μm in Ra as and JP2010-217871 A, there sometimes arises a problem that a light blockingeffect that is a basic effect of optical sheets deteriorates.

In view of the above problems, an object of the present invention is toprovide an optical sheet that makes it possible to keep efficiency oflight utilization high or to prevent something bad from occurring in ascreen like interference fringes, while having a light blocking effect.In addition, the present invention provides an image source unit and animage display device each including the optical sheet.

Solution to Problem

One aspect of the present disclosure is a laminate having a plurality oflayers, the laminate comprising: a substrate layer; and an opticalfunction layer that is layered on one surface of the substrate layer,and has a plurality of light transmission parts which are arranged in arow along a surface of the substrate layer so as to belight-transmissive, and light absorption parts in a row, each of whichis arranged between adjacent ones of the light transmission parts so asto be light-absorptive, wherein on a cross section of the opticalfunction layer in a layer thickness direction, a cross-sectional area ofone of the light transmission parts to a total cross-sectional area ofone of the light transmission parts and one of the light absorptionparts which are adjacent to each other is 78.2% to 88.5%, and whenirradiation light inclining at 45° from a normal line of the opticalfunction layer is irradiated in a direction of alternately aligning thelight transmission parts and the light absorbing parts of the opticalfunction layer, and omnidirectional light when 45° specular reflectedlight is excluded from reflected light of this irradiation light isdefined as an optical diffuse reflectance, an optical diffusereflectance on a light output surface side of the laminate is 1.9% to3.5%. An optical diffuse reflectance on a light input surface side ofthe laminate may be 2.5% to 5.0%.

Another aspect of the present disclosure is a laminate having aplurality of layers, the laminate comprising: a substrate layer; anoptical function layer that is layered on one surface of the substratelayer, and has a plurality of light transmission parts which arearranged in a row along a surface of the substrate layer so as to belight-transmissive, and light absorption parts in a row, each of whichis arranged between adjacent ones of the light transmission parts so asto be light-absorptive; and a reflective polarizing plate that isarranged on the optical function layer on a side opposite to thesubstrate layer, wherein on a cross section of the optical functionlayer in a layer thickness direction, a cross-sectional area of one ofthe light transmission parts to a total cross-sectional area of one ofthe light transmission parts and one of the light absorption parts whichare adjacent to each other is 78.2% to 88.5%, and when irradiation lightinclining at 45° from a normal line of the optical function layer isirradiated in a direction of alternately aligning the light transmissionparts and the light absorbing parts of the optical function layer, andomnidirectional light when 45° specular reflected light is excluded fromreflected light of this irradiation light is defined as an opticaldiffuse reflectance, an optical diffuse reflectance on a light inputsurface side of the laminate is 8.2% to 9.7%.

In the laminate, a cross section of each of the light transmission partsin the layer thickness direction may be a trapezoid.

Provided is an image source unit comprising a liquid crystal panel thatis arranged on a light output side of the laminate.

Also provided is an image display device comprising: a housing; and theimage source unit that is arranged inside the housing.

Advantageous Effects of Invention

The optical sheet makes it possible to keep efficiency of lightutilization high or to prevent something bad from occurring in a screenlike interference fringes, while having a light blocking effect.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an external perspective view of an image display device 1;

FIG. 2 is an exploded perspective view of an image source unit 5;

FIG. 3 is a cross-sectional view to explain the layer structure of theimage source unit 5;

FIG. 4 is an enlarged view focusing on an optical function layer 21;

FIG. 5 is a cross-sectional view to explain a layer structure of animage source unit 105;

FIG. 6A is a view to explain an optical function layer 21′;

FIG. 6B is a view to explain an optical function layer 21″;

FIG. 7 is a view to explain an embodiment of an optical function layerNo. 1;

FIG. 8 is a view to explain an embodiment of an optical function layerNo. 2;

FIG. 9 is a view to explain an embodiment of an optical function layerNo. 3;

FIG. 10 is a view to explain an embodiment of an optical function layerNo. 4;

FIG. 11 is a view to explain an embodiment of an optical function layerNo. 5;

FIG. 12 is a view to explain an embodiment of an optical function layerNo. 6;

FIG. 13 is a view to explain an embodiment of an optical function layerNo. 7;

FIG. 14 is a view to explain an embodiment of an optical function layerNo. 8;

FIG. 15 is a view to explain an embodiment of an optical function layerNo. 9;

FIG. 16A is a view to explain measurement of an optical diffusereflectance on the light output side in Test B;

FIG. 16B is a view to explain measurement of an optical diffusereflectance on the light input side in Test B;

FIG. 17 is a view to explain an embodiment of an optical function layerNo. 21;

FIG. 18 is a view to explain an embodiment of an optical function layerNo. 22;

FIG. 19 is a view to explain an embodiment of an optical function layerNo. 23;

FIG. 20 is a view to explain an embodiment of optical function layersNos. 24 and 25;

FIG. 21A is a view to explain measurement of an optical diffusereflectance on the light output side in Test C; and

FIG. 21B is a view to explain measurement of an optical diffusereflectance on the light input side in Test C.

DESCRIPTION OF EMBODIMENTS

Hereinafter each embodiment will be described based on the drawings. Thepresent invention is not limited to these embodiments. Because most ofelements included in each embodiment are actually very minute or verythin layers, parts of the elements are varied, enlarged, etc. to beshown in the drawings for understandability. While signs are appended tothe elements, parts of signs which are repeated are sometimes omittedfor visibility.

FIG. 1 is a view to explain one embodiment, and is a perspective viewshowing an image display device 1 including an image source unit 5. Theright on the page of FIG. 1 is an observer side. Here, the image displaydevice 1 of this embodiment is an image display device for the use incars, and examples thereof include a car navigation device. The imagedisplay device 1 includes a housing 2. The image source unit 5 is builtin inside the housing 2.

The housing 2 forms an outer shell of the image display device 1. Thehousing 2 is a member that houses thereinside almost all the membersconstituting the image display device. The housing 2 has an opening. Aso-called screen portion of the image source unit 5 is exposed throughthe opening, which makes it possible to be visually recognized. Theimage display device 1 includes other various known components forfunctioning as an image display device.

FIG. 2 is an exploded perspective view of the image source unit 5. FIG.2 separately shows part of the layers that constitute the image sourceunit for understandability. Actually, the layers directly overlie eachother or the like, to be layered (see FIG. 3). FIG. 3 is across-sectional view in a thickness direction, including the line shownby III-III in FIG. 2 (the line in a vertical direction). When the imagesource unit 5 is disposed in the image display device 1, the right ofthe sheet of each of FIGS. 2 and 3 is an observer side, and the leftthereof is a light source side.

The image source unit 5 is composed of an image source 10 and a functionlayer 30 that is arranged in an image emission side of the image source10 (that is, in the observer side).

This embodiment is structured to include a liquid crystal panel 12 inthe image source 10. Specifically, the image source 10 includes asurface light source device 11, an optical sheet 20 and the liquidcrystal panel 12. That is, in this embodiment, the optical sheet 20 isarranged between the surface light source device 11 and the liquidcrystal panel 12.

Here, the surface light source device 11 and the liquid crystal panel 12of known structures can be used.

Examples of the surface light source device 11 include a surface lightsource device composed of a reflection sheet, a light guide plate (alight emission source is arranged in its side surface), a diffusionsheet, a lens (prism) sheet and a reflective polarizing sheet, which arelayered in this order from the light source side (the left on the pageof FIG. 3) to the observer side (the right thereof). That is, in thisembodiment, the optical sheet 20 is layered on the reflective polarizingsheet.

Examples of the liquid crystal panel 12 include a liquid crystal panelcomposed of a polarizing film, a glass substrate, a liquid crystallayer, a glass substrate and a polarizing film, which are layered inthis order from the light source side (the left on the page of FIG. 3)to the observer side (the right thereof).

In this embodiment, the optical sheet 20 consists of a plurality oflayers, and is arranged between the surface light source device 11 andthe liquid crystal panel 12 in a light emission side of the surfacelight source device 11. In this embodiment, the optical sheet 20includes an optical function layer 21 and a substrate layer 25, whichare arranged in this order from the side of the surface light sourcedevice 11. Each of the layers will be described below. For convenience,the substrate layer 25 will be described first, and after that, theoptical function layer 21 will be described.

The substrate layer 25 is a layer that is a substrate for forming theoptical function layer 21 on one surface thereof. The substrate layer25, having translucency, supports the optical function layer 21 so as toprevent the optical function layer 21 from deforming. In view of this,concrete examples of materials that constitute the substrate layer 25include transparent resin mainly constituted by an acrylic resin,styrene, polycarbonate, polyethylene terephthalate (PET), acrylonitrileand/or triacetyl cellulose (TAC), and epoxy acrylate and urethaneacrylate based reactive resin (such as ionizing radiation curable typeresin).

Among them, it is preferable to use TAC, a methacrylate resin and/orpolycarbonate, which is/are with low birefringence, in view of thecombination with the liquid crystal panel. Further, it is desirable touse polycarbonate, which has a high glass transition temperature, forthe use in cars and so on where a high heat resisting property isrequired. Specifically, the glass transition temperature ofpolycarbonate is 143° C. Polycarbonate is suitable for the use in cars,where durability at 105° C. is generally required.

Non-limiting thickness of the substrate layer 25 is preferably 25 μm to300 μm. There is a risk that some problem occurs in processability in acase where thickness of the substrate layer 25 is out of the aboverange. For example, creases tend to be generated on the substrate layer25 thinner than 25 μm. If the substrate layer 25 is thicker than 300 μm,it gets difficult to roll up the optical sheet 20.

A surface of the substrate layer 25 which is not in touch with theoptical function layer 21 may be a rough surface. In a case where arough surface is formed, its surface roughness is preferably 0.1 μm to0.2 μm in Ra (μm) (JIS B 0601 (2001) arithmetical mean roughness). Thesurface roughness within the above range makes it possible to besuppressed: generation of interference fringes due to so-called opticalcontact when the optical sheet 20 touches other layers; and generationof something bad in the exterior view such as scintillation (so-calledglare on the screen), which originates from people's easy recognition ofunevenness based on the roughness.

In this embodiment, the optical function layer 21 has a function ofchanging a direction of an image light to the front direction, andabsorbing part of an image light that is emitted by the image source 10,so that the image light is not reflected in a windshield of a car. Thatis, the optical function layer 21 is a layer having a light blockingeffect of controlling a direction where light travels. FIG. 4 shows apartially enlarged view of FIG. 3, focusing on the optical functionlayer 21.

In this embodiment, the optical function layer 21 has a cross sectionshown in FIGS. 3 and 4, and has a shape extending in a direction intoand out of the page. In this embodiment, this extending direction is ahorizontal direction in a state where the image display device 1 isinstalled in a car. This prevents an image light from being reflected ina windshield as described below.

The optical function layer 21 includes light transmission parts 22,which are trapezoids on the cross section appearing in FIGS. 3 and 4,and light absorption parts 23 having cross sections of trapezoids, eachof which is formed between two adjacent light transmission parts 22.Thus, in this embodiment, the light transmission parts 22 and the lightabsorption parts 23 are arranged in a row alternately in a verticaldirection in a state where the image display device 1 is installed in acar.

A light transmission part 22 is a part whose main function is totransmit light. In this embodiment, the light transmission part 22 is anisosceles trapezoid having a longer lower base in the substrate layer 25side (observer side) and a shorter upper base in the opposite side(surface light source device 11 side), on the cross section appearing inFIGS. 3 and 4. The light transmission part 22 extends along a surface ofthe substrate layer 25 while keeping the cross section, and some lighttransmission parts 22 are arranged in a row at intervals in a directiondifferent from this extending direction. A space of a trapezoidal crosssection is formed between adjacent light transmission parts 22. Thus,this space has the trapezoidal cross section of a longer lower base inthe upper base side of the light transmission part 22 and a shorterupper base in the lower base side of the light transmission part 22. Thespace is filled with necessary materials described later, which forms alight absorption part 23. This embodiment has a linking part 24 thatlinks the adjacent light transmission parts 22 together in their longerlower base sides.

A refractive index of the light transmission part 22 is represented byNt. Such a light transmission part 22 can be formed by curingtransmission part constituting components. A non-limiting value of therefractive index Nt is preferably no less than 1.55 in view of propertotal reflection of light on the interface between inclines of thetrapezoidal cross sections of the light transmission part 22 and thelight absorption part 23 as described below. More preferably therefractive index is no less than 1.56. It is noted that the refractiveindex Nt is preferably no more than 1.61 because most of materials ofexcessively high refractive indexes easy to crack.

Here, examples of components constituting the light transmission partinclude epoxy acrylate, urethane acrylate, polyether acrylate, polyesteracrylate and polythiol based ionizing radiation (like ultraviolet)curable type resin.

The light absorption part 23 is arranged in the above described spacethat is formed between the adjacent light transmission parts 22, and itsshape of a cross section is the same as that of the space. Therefore,the cross section of the light absorption part 23 is an isoscelestrapezoid whose shorter upper base faces the substrate layer 25 side(observer side) and whose longer lower base faces the opposite side(surface light source device 11 side). A refractive index of the lightabsorption part 23 is represented by Nr. The light absorption part 23 isconfigured so as to be able to absorb light. Specifically, lightabsorbing particles disperse into binder having the refractive index ofNr. The refractive index Nr is lower than the refractive index Nt of thelight transmission part 22. A non-limiting value of the refractive indexNr is preferably no more than 1.50, and more preferably no more than1.49. The reference index Nr is preferably no less than 1.47 in view ofavailability.

Non-limiting difference between the refractive index Nt of the lighttransmission part 22 and the refractive index Nr of the light absorptionpart 23 is preferably no less than 0.05. As well, a non-limiting upperlimit of the difference in refractive index is preferably no more than0.14 in view of availability of materials.

Non-limiting examples of materials used as the binder here includephotocurable resin such as urethane (meth)acrylate, polyester(meth)acrylate, epoxy (meth)acrylate and butadiene (meth)acrylate.

While light absorbing colored particles such as carbon black arepreferably used as the light absorbing particles, the light absorbingparticles are not limited thereto. Colored particles that selectivelyabsorb a specific wavelength may be used for the light absorbingparticles depending on characteristics of an image light. Specificexamples of colored particles include carbon black, graphite, metallicsalts such as black iron oxide, organic fine particles colored withdyes, pigments and the like, and colored glass beads. Especially,colored organic fine particles are preferably used in view of the cost,quality, availability and so on. An average particle size of coloredparticles is preferably 0.01 μm to 20 μm.

In this embodiment, 78.2% to 88.5% is a percentage of thecross-sectional area of the light transmission part 22 in the totalcross-sectional area of one adjacent light transmission part 22 andlight absorption part 23 (this is the cross-sectional area that is onthe cross section appearing in FIG. 4, and that is in the directionorthogonal to the direction where the light transmission part 22 and thelight absorption part 23 extend) (this percentage is referred to as “aproportion of the cross-sectional area of the light transmission part”).Here, the light transmission part 22 is that existing between adjacentlight absorption parts 23, and in this embodiment, the cross-sectionalarea of the light transmission part 22 is that of an isoscelestrapezoid, as shown by S1 in FIG. 4. The cross-sectional area of thelight absorption part 23 is that of an isosceles trapezoid in thisembodiment as shown by S2 in FIG. 4.

This makes it possible to realize a high level of the efficiency oflight utilization while a predetermined light blocking effect is kept.If the proportion of the cross-sectional area of the light transmissionpart is smaller than 78.2%, the efficiency of utilization of lightsupplied from the light source gets low. In contrast, if the proportionof the cross-sectional area of the light transmission part is beyond88.5%, the light blocking effect deteriorates, which results intransmission of light that is to be removed. In addition, if theproportion of the cross-sectional area of the light transmission part isbeyond 88.5%, the light absorption part gets minuter, which makes itdifficult to make the light absorption part of a high accuracy.

There is nothing special to be limited in addition to the above. Thelight transmission part 22 and the light absorption part 23 may beformed as follows as an example. That is, a pitch of the lighttransmission part 22 and the light absorption part 23, which is shown byPk in FIG. 3, is preferably 30 μm to 100 μm. It is also preferable that:the interface between inclines of the light absorption part 23 and thelight transmission part 22, and a normal line to the surface of theoptical function layer 21 be at an angle within the range of 0° to 10°,which is shown by θk in FIG. 4. It is also preferable that thickness ofthe light absorption part 23, which is shown by Dk in FIG. 3, be 60 μmto 150 μm. The pitch, angle and thickness within the above ranges allowsbalance between light transmission and light absorption to be muchbetter.

This embodiment illustrates that the interface between the lighttransmission part 22 and the light absorption part 23 (leg part) is in astraight line on the cross section. The interface is not limitedthereto, and may be in a zigzag line, a curved convex surface, a curvedconcave surface, or the like. A plurality of the light transmissionparts 22 and the light absorption parts 23 may have the same shape ofthe cross sections, and may have different shapes thereof withpredetermined regularities.

In this embodiment, the optical diffuse reflectance measured on thelight output side of the optical sheet 20 can be within a predeterminedrange that will be shown later. This makes it possible to preventinterference fringes and scintillation, and at the same time to highlysecure a demanded light blocking effect of the optical sheet 20. If thisoptical diffuse reflectance is lower than the predetermined range,interference fringes and scintillation (glare) are easy to be generated.In contrast, if this optical diffuse reflectance is higher than thepredetermined range, there is a risk that some problem arises in thelight blocking effect. The details of a method for measuring the opticaldiffuse reflectance will be described later.

A means for making the optical diffuse reflectance measured on the lightoutput side of the optical sheet 20 within the predetermined range isnot especially limited. Examples of this means include known lightdiffusing means such as: making a surface of the substrate layer 25rough; and dispersing light-scattering particles into the substratelayer 25.

Such an optical diffuse reflectance is not decided only depending on amode of the light diffusing means, but is also influenced by modes ofthe light transmission part and the light absorption part. Thus, theoptical diffuse reflectance is related to a whole mode of the opticalsheet.

Further, the optical diffuse reflectance measured on the light inputside of the optical sheet 20 is preferably within a predetermined rangethat will be shown later. This makes it possible to suppressscintillation (so-called glare).

The details of a method for obtaining the optical diffuse reflectance onthe light input side will be described later.

Nothing particular is limited in order to obtain such an optical diffusereflectance on the light input side, and the light input surface of theoptical function layer 21 may be adjusted. In addition, for example, astructure as shown in FIG. 5 can be taken. FIG. 5 corresponds to FIG. 3,and is a cross-sectional view showing a layer structure of an imagesource unit 105. The image source unit 105 includes an optical sheet120. This optical sheet 120 is structured so that a transparent resinlayer 121 is layered on a surface of the above described opticalfunction layer 21 of the optical sheet 20 in the side opposite to thesubstrate layer 25. The optical diffuse reflectance on its light inputside can be a desired value by employing light diffusing means such as:making a surface of the transparent resin layer 121 rough; containinglight-scattering particles in the transparent resin layer 121; andemploying both means.

In this case as well, the optical diffuse reflectance is not decidedonly depending on a mode of the light diffusing means, but is alsoinfluenced by modes of the light transmission part and the lightabsorption part. Thus, the optical diffuse reflectance is related to awhole mode of the optical sheet.

When the optical sheet 20 and the reflective polarizing plate that isarranged on the light input side of the optical sheet 20 are combined toform a laminate, the optical diffuse reflectance measured on the lightoutput side of the optical sheet 20 can be within a predetermined rangethat will be shown later. This also makes it possible to preventinterference fringes and scintillation, and at the same time to highlysecure a demanded light blocking effect of the optical sheet 20.

Further, in the laminate of the combination of the optical sheet 20 andthe reflective polarizing plate, the optical diffuse reflectancemeasured on the light input side of the optical sheet 20 can be within apredetermined range that will be shown later. This also makes itpossible to suppress scintillation (so-called glare).

The details of measurement of the optical diffuse reflectances in thesecases will be described later as well.

FIGS. 6A and 6B each show an example of asymmetric leg parts in atrapezoidal cross section. FIGS. 6A and 6B correspond to FIG. 4. FIG. 6Ashows an example of an optical function layer 21′ and FIG. 6B shows anexample of an optical function layer 21″.

The optical function layer 21′ shown in FIG. 6A has light transmissionparts 22′ and light absorption parts 23′. Materials constituting this,and ways of grasping its refractive index, proportion of the area of thelight transmission part, and the optical diffuse reflectance are thesame as those of the optical function layer 21.

As is seen from FIG. 6A, the leg parts of the light absorption part 23′in the trapezoidal cross section have a further feature in this example.Two leg parts of the light absorption part 23′ form different angleswith a normal line to a layer surface of the optical function layer 21′.In more detail, the angle formed by a leg part 23′a, which is a lowerleg part in a state where the image display device is installed, issmaller than that formed by a leg part 23′b, which is an upper leg partin this state. More preferably, the angle formed by the leg part 23′a is0° (that is, the leg part 23′a is parallel to the normal line to thelayer surface of the optical function layer 23′). This makes it possibleto efficiently suppress light (image light) travelling upward, and tofurther suppress reflection in a windshield in a case of installation ina car.

In contrast, the optical function layer 21″ shown in FIG. 6B has lighttransmission parts 22″ and light absorption parts 23″. Ways of graspingits proportion of the area of the light transmission part, and theoptical diffuse reflectance are the same as those of the opticalfunction layer 21. The optical function layer 21″ has a mode thatinclines of the leg parts have an inverse relationship to those of theoptical function layer 21′. Whereby emission of image light diagonallyupward increases. In a case where it is no problem to reflect light in awindshield, a clear image can be observed in a view diagonally upward.

Such an optical sheet 20 is made as follows for example.

First, the light transmission part 22 is formed on one surface of thesubstrate layer 25. For this, a substrate sheet that is to be thesubstrate layer 25 is inserted between a mold roll having such a shapeon its surface that the shape of the light transmission part 22 can becopied thereon and a nip roll arranged so as to face the mold roll.Then, the mold roll and the nip roll are rotated while composition forconstituting the light transmission part is supplied between thesubstrate sheet and the mold roll. Whereby, the composition forconstituting the light transmission part is filled into grooves (have ashape of an inverted light transmission part) formed on the surface ofthe mold roll, which correspond to the light transmission part, and thusthe shape of the composition corresponds to that of the surface of themold roll.

The composition for constituting the light transmission part, which issandwiched and filled between the mold roll and the substrate sheet, isirradiated with light for curing in the substrate sheet side by a lightirradiation device, which makes it possible to cure the composition andfix its shape. Then, the substrate layer 25 and the molded lighttransmission part 22 are separated from the mold roll by means of arelease roll.

Next, the light absorption part 23 is formed. In order to form the lightabsorption part 23, first, composition for constituting the lightabsorption part is filled into intervals between the above molded lighttransmission parts 22. Thereafter, an excessive amount of thecomposition is scraped off by a doctor blade or the like. Then, theremaining composition is irradiated with ultraviolet rays in the lighttransmission part 22 side to be cured, to form the light absorption part23.

Examples of the function layer 30 include known layers arranged nearerto the observer side than the liquid crystal panel and having variousfunctions, such as anti-reflection layers, anti-glare layers andhardcoat layers.

The image source unit 5 having the structure as described above can bemade as follows for example: that is, the made optical sheet 20 isarranged in the light emission side of the surface light source device11 so that a side thereof opposite to the substrate layer 25 (that is,the optical function layer 21) faces the surface light source device 11.The liquid crystal panel 12 and the function layer 30 are layered on theobserver side of the optical sheet 20.

The image source unit 5 structured as above is housed into the housing2, and the housing 2 is arranged so that the function layer 30 side isin the observer side, which makes it possible to structure the imagedisplay device 1. At this time, electric circuits, power supply circuitsand the like for operating the image source unit 5 are also provided ifnecessary.

Such an image display device is installed in a car, and operates asfollows for example, which will be described with examples of opticalpaths. These examples of optical paths are for the description andconceptual, and do not illustrate reflection, refraction or the likestrictly.

When the image display device 1 is operated, the surface light sourcedevice 11 emits lighting as shown in FIG. 3. Light L10 emitted by thesurface light source device 11 transmits the optical sheet 20 withoutreaching any interface between the light transmission part 22 and thelight absorption part 23, transmits the liquid crystal panel 12 asobtaining image information in the liquid crystal panel 12, and alsotransmits the function layer 30, to reach the observer side. An observercan observe the image light.

Light L11 emitted by the surface light source device 11 reaches aninterface between the light transmission part 22 and the lightabsorption part 23. Total reflection occurs in the light L11 in relationto difference between both in refractive index and its incidence angleat the interface. The light L11 transmits the liquid crystal panel 12 asobtaining image information in the liquid crystal panel 12, and alsotransmits the function layer 30, to be emitted in the observer side. Atthis time, since the interface between the light transmission part 22and the light absorption part 23 inclines to the normal line to thelight output surface of the optical sheet 20 as described above, thedirection of the light L11 is changed downward, and the light is blockedfrom travelling upward (light blocking is carried out), which preventsthe light L11 from being reflected in a windshield. Since the light L11directs in the front direction, such light L11 also contributes toimprovement of front brightness of image light.

Light L12 emitted by the surface light source device 11 reaches aninterface between the light transmission part 22 and the lightabsorption part 23, transmits the interface in relation to differencebetween both in refractive index and its incidence angle at theinterface, and is absorbed by the light absorption part 23. This blocksthe light from travelling upward (light blocking is carried out), andprevents the light from being reflected in a windshield.

Since the proportion of the cross-sectional area of the lighttransmission part is constituted as described above in this embodiment,a stray light like the light L12 is absorbed, and at the same time lightemitted in the observer side like the light L10 and the light L11 can beefficiently obtained, which makes it possible to keep the efficiency ofutilization of light high.

The optical diffuse reflectance in at least the light output side of theoptical sheet is constituted as described above in this embodiment,occurrence of interference fringes can be suppressed, and light can beblocked from travelling in an unintended direction due to diffusion ofthe light (in this embodiment, reflection in a windshield due to lighttravelling upward), which makes it possible to carry out light blocking.Therefore, a high light blocking effect can be kept, and high frontbrightness can be achieved.

<Test A>

As Test A, optical sheets according to nine examples where the shapes ofthe cross sections of the light transmission parts and the lightabsorption parts varied (Nos. 1 to 9) were made, to check the efficiencyof light utilization.

(No. 1)

In No. 1, an optical sheet that included an optical function layerhaving a shape of the cross section shown in FIG. 7 was made. Thisoptical sheet was formed of the optical function layer and a substratelayer, and was made by the above described method.

More specifically, polycarbonate resin of 130 μm in thickness was usedfor the substrate layer.

UV-curable urethane acrylate of 1.56 in refractive index was used forthe light transmission part. The cross section of the light transmissionpart was an isosceles trapezoid of 29 μm in upper base, 35 μm in lowerbase and 102 μm in height.

UV-curable urethane acrylate of 1.49 in refractive index was used forthe binder of the light absorption part. Acrylic beads containing carbonblack was included in the binder so that the content thereof was 25 mass% on the basis of the whole of the composition constituting the lightabsorption part. The cross section of the light absorption part was anisosceles trapezoid of 4 μm in upper base, 10 μm in lower base and 102μm in height.

The linking part was 25 μm in thickness (Tk in FIG. 3).

A 6.5-inch liquid crystal display (LQ65T5GG03, manufactured by SharpCorporation) was equipped with each of the optical sheets as the above,to be a liquid crystal display. More specifically, the optical sheet wasarranged in the light output surface side of a surface light sourcedevice that consisted of a light guide plate in a side surface of whicha light emission source was arranged, a prism sheet, a light diffusionfilm and a reflective polarizing plate; and a liquid crystal panel wasarranged in the light output surface side of the optical sheet.

(No. 2)

No. 2 was the same as No. 1 except that the shapes of the cross sectionsof the light transmission parts and the light absorption parts werechanged as FIG. 8.

(No. 3)

No. 3 was the same as No. 1 except that the shapes of the cross sectionsof the light transmission parts and the light absorption parts werechanged as FIG. 9.

(No. 4)

The example shown in FIG. 5 was followed by No. 4. No. 4 was an examplethat angles of inclination of two leg parts of the light transmissionpart and the light absorption part were different. Specifically, theshapes of the cross sections of the light transmission parts and thelight absorption parts were changed as FIG. 10. Here, an angle ofinclination of the leg part 23′a was 0° (that is, the leg part 23′a wasparallel to the normal line to the layer surface of the optical sheet).Other details were the same as No. 1.

(No. 5)

No. 5 was the same as No. 4 except that the shapes of the cross sectionsof the light transmission parts and the light absorption parts werechanged as FIG. 11.

(No. 6)

No. 6 was the same as No. 4 except that the shapes of the cross sectionsof the light transmission parts and the light absorption parts werechanged as FIG. 12.

(No. 7)

No. 7 was the same as No. 1 except that the shapes of the cross sectionsof the light transmission parts and the light absorption parts werechanged as FIG. 13. Here, some signs used in FIGS. 13 to 15 represent anoptical function layer 121, a light transmission part 122 and a lightabsorption part 123.

(No. 8)

No. 8 was the same as No. 7 except that the shapes of the cross sectionsof the light transmission parts and the light absorption parts werechanged as FIG. 14.

(No. 9)

No. 9 was the same as No. 7 except that the shapes of the cross sectionsof the light transmission parts and the light absorption parts werechanged as FIG. 15.

Assuming that the normal line direction of the optical sheet was 0°,brightness of each of the above made liquid crystal displays accordingto Nos. 1 to 9 was measured with EZContrast (manufactured by ELDIM) atthe normal line direction and every 10° of inclination from the normalline direction to ±80° in a direction of aligning the light transmissionparts and the light absorption parts alternately. Then, their integratedvalues of brightness were obtained. Thus, it could be said that a largerintegrated value of brightness indicated more light emission, which wasaccompanied by high efficiency of light utilization.

In contrast, as to a light blocking effect, assuming that the normalline direction of the optical sheet was 0°, brightness was measured withEZContrast (manufactured by ELDIM) at the normal line direction andevery 10° of inclination from the normal line to ±80° in the directionof aligning the light transmission parts and the light absorption partsalternately. Then, brightness at 45° (the mean of 40° and 50° inbrightness) was measured and represented in percentage terms assumingthat the front brightness was 100%. A case where a value represented inpercentage terms was no more than 10% was regarded as a good lightblocking effect.

Table 1 shows characteristic shapes of the light transmission parts andthe light absorption parts other than the above description and themeasurement results.

“Proportion of cross-sectional area of light transmission part (%)”represents a percentage of the cross-sectional area of the lighttransmission part 22 or 122 in the total cross-sectional area of oneadjacent light transmission part 22 or 122 and light absorption part 23or 123, respectively. That is, this percentage can be calculated by“area of one light transmission part/(area of one light transmissionpart+area of one light absorption part)” in each cross section shown inFIGS. 7 to 15.

“Proportion of opening (%)” represents a proportion of an area of thelight transmission part 22 or 122 per pitch on a surface side of theoptical function layer where incident light comes (in these examples,the shorter upper base side of the light transmission part 22 or 122).That is, this proportion can be calculated by “a length of the upperbase of one light transmission part/(a length of the upper base of onelight transmission part+a length of the lower base of one lightabsorption part)” in each cross section shown in FIGS. 7 to 15.

“Integrated brightness” and “Light blocking effect” are as describedabove.

TABLE 1 Proportion of Proportion Integrated Light cross-sectional areaof of opening brightness blocking light transmission part (%) (%)(cd/m²) effect No. 1 82.1 74.4 2841 6.7% No. 2 78.2 71.8 2610 5.2% No. 388.5 82.1 3200 9.8% No. 4 82.1 74.4 2841 6.7% No. 5 78.2 71.8 2610 5.2%No. 6 88.5 82.1 3200 9.8% No. 7 72.3 53.2 2450 4.7% No. 8 78.1 75.0 25874.5% No. 9 76.7 69.8 2530 7.0%

As is seen from Table 1, the integrated brightness of Nos. 1 to 6 waslarger than that of Nos. 7 to 9, and the efficiency of light utilizationin Nos. 1 to 6 was found to be high. Here, as is seen from thecomparison between, for example, No. 1 and No. 2, even if theproportions of openings were approximately the same, the integratedbrightness largely differed. All examples had no more than 10% of alight blocking effect, which was good.

<Test B>

In Test B, liquid crystal displays were made with laminates havingoptical sheets according to examples where the optical diffusereflectances on the light input sides and the optical diffusereflectances on the light output sides varied (Nos. 11 to 18), to checkinterference fringes, scintillation (glares) and a light blockingeffect.

An optical sheet that included an optical function layer having lighttransmission parts and light absorption parts whose shapes of the crosssections were as shown in FIG. 4 was made. More particularly, thisoptical sheet was formed of the optical function layer, a substratelayer, and a layer having micro-roughness.

Further specifically, matte polycarbonate resin of 130 μm in thicknesswas used for the substrate layer. That is, a micro-roughness surfaceformed on a metal mold was copied on a surface of the substrate layerwhich was on the side opposite to the optical function layer, to formmicro-roughness (matte surface).

UV-curable urethane acrylate of 1.56 in refractive index was used forthe light transmission part. The cross section of the light transmissionpart was an isosceles trapezoid of 29 μm in upper base, 35 μm in lowerbase and 102 μm in height (Dk in FIG. 3).

UV-curable urethane acrylate of 1.49 in refractive index was used forthe binder of the light absorption part. Acrylic beads containing carbonblack was included in the binder so that the content thereof was 25 mass% on the basis of the whole of the composition constituting the lightabsorption part. The cross section of the light absorption part was anisosceles trapezoid of 4 μm in upper base, 10 μm in lower base and 102μm in height (Dk in FIG. 3); The linking part was 25 μm in thickness (Tkin FIG. 3).

In addition, a layer having micro-roughness (matte) was formed of thematerials same as the light transmission part, on a surface of theoptical function layer which was on the side opposite to the substratelayer, with a metal mold having a micro-roughness surface. Whereby, theoptical sheet whose thickness was 280 μm, which was total thickness ofthe substrate layer, the optical function layer and the layer havingmicro-roughness, was obtained.

The optical diffuse reflectance on the light input side and the opticaldiffuse reflectance on the light output side were adjusted according tothe substrate layers, and change in degree of micro-roughness (surfaceroughness) provided on the surface of any metal mold for forming thelayer having micro-roughness, to obtain the optical sheets of Nos. 11 to18. Micro-roughness provided on the surface of the metal molds wasformed by copper-plating on the surface of the metal molds and blastingprocess on the copper plating with glass beads. Its roughness wasadjusted according to diameters of the beads for the blasting processand pressure for the blasting process.

The optical diffuse reflectance on the light input side and the opticaldiffuse reflectance on the light output side of the optical sheet ofeach example as described above were measured as follows.

An optical diffuse reflectance is defined by an omnidirectional opticaldiffuse reflectance that was obtained by excluding a reflectance ofspecular reflected light from the total reflectance. Specifically, theoptical diffuse reflectance was measured using a haze meter (HR-100 byMurakami Color Research Laboratory, measurement condition: reflection)as shown in FIGS. 16A and 16B, which is described in more detail asfollows.

A layer to be measured (substrate layer or light diffuser layer) of theoptical sheet was directed toward the light input side (integratingsphere side), and a light trapping box that absorbed reaching light wasarranged on the opposite side thereof. That is, FIG. 16A showsmeasurement of the optical diffuse reflectance on the light input side,and FIG. 16B shows measurement of the optical diffuse reflectance on thelight output side. A standard white board (barium sulfate, reflectance:98.3%) was arranged at the position of the light trapping box beforemeasurement, to carry out an initial setting, and thereafter the lighttrapping box was arranged instead of the standard white board, toconduct measurement.

The optical sheet arranged as described above was irradiated in adirection of alternately aligning the light transmission parts and lightabsorbing parts with irradiation light (light source D65) inclined at45° from the normal line of the optical sheet.

In the irradiation light, 45° specular reflected light was excluded fromthe light reflected by the optical sheet, to obtain omnidirectionallight in the integrating sphere at this time by a detector. This wasdiffuse reflection light. The proportion of the omnidirectional light(diffuse reflection light) to the irradiation light represented in termsof percentage was “optical diffuse reflectance”.

While a light trapping box was used for this measurement of opticaldiffuse reflectance, a method of excluding the transmission lightthrough the optical sheet but not returning this light to theintegrating sphere was applied as well.

A liquid crystal display of 6.5-inch (LQ65T5GG03 manufactured by SharpCorporation) was equipped with each of the optical sheets as the above,to be a liquid crystal display. More specifically, an optical sheet wasarranged on the light output surface side of a surface light sourcedevice that consisted of a light guide plate on a side surface of whicha light emission source was arranged, a prism sheet, a light diffusionfilm and a reflective polarizing plate; and a liquid crystal panel wasarranged on the light output surface side of the optical sheet.

A light blocking effect, occurrence of interference fringes andscintillation (glare) of each of the above made liquid crystal displaysaccording to Nos. 11 to 18 were evaluated visually.

As to “Light blocking effect”, assuming that the normal line directionof the optical sheet was 0°, brightness was measured at the normal linedirection and every 10° of inclination from the normal line to ±80° withEZContrast (manufactured by ELDIM). Then, a case where a proportion ofbrightness at 45° (the mean of 40° and 50° in brightness) in the frontbrightness was no more than 7% was regarded as a good light blockingeffect, and is indicated by an open circle. A case where this proportionwas no less than 7% is indicated by a cross.

It was checked whether “Interference fringe” and “Scintillation”occurred visually upon turning off the liquid crystal display. A casewhere no fringe and scintillation occurred is indicated by an opencircle, and a case where fringe or scintillation occurred is indicatedby a cross.

The results are shown in Table 2.

TABLE 2 Optical Optical diffuse diffuse reflectance reflectance on onlight light Light output input blocking Interference side (%) side (%)effect fringe scintillation No. 11 3.2 2.9 ∘ ∘ ∘ No. 12 3.2 3.8 ∘ ∘ ∘No. 13 1.9 2.5 ∘ ∘ ∘ No. 14 3.5 5.0 ∘ ∘ ∘ No. 15 3.5 2.5 ∘ ∘ ∘ No. 161.9 5.0 ∘ ∘ ∘ No. 17 1.5 1.9 ∘ x x No. 18 3.8 3.2 x ∘ ∘

As is seen from Table 2, in the case where the optical diffusereflectance on the light output surface side of the optical sheet is1.9% to 3.5%, all of a light blocking effect, interference fringe andscintillation can be “good” according to Nos. 11 to 16.

In contrast, in the case where the optical diffuse reflectance on thelight input surface side is 2.5% to 5.0%, all of a light blockingeffect, interference fringe and scintillation can be “good” according toNos. 11 to 16.

<Test C>

As Test C, laminates having optical sheets where the shapes of the crosssections of the light transmission parts and the light absorption partsetc. varied were made, to check their performances.

(No. 21)

In No. 21, a laminate that includes an optical function layer having across section shown in FIG. 17 was made. This laminate was formed of asubstrate layer, the optical function layer, a reflective polarizingplate, and a layer having micro-roughness. The optical function layerand the reflective polarizing plate were integrated by an adhesivelayer.

Further specifically, matte polycarbonate resin of 130 μm in thicknesswas used for the substrate layer. That is, a micro-roughness surfaceformed on a metal mold was copied on a surface of the substrate layerwhich was on the side opposite to the optical function layer, to formmicro-roughness (matte surface).

UV-curable urethane acrylate of 1.56 in refractive index was used forthe light transmission part 22′ of the optical function layer. The crosssection of the light transmission part 22′ was a trapezoid of 49 μm inupper base, 53 μm in lower base and 150 μm in height.

UV-curable urethane acrylate of 1.49 in refractive index was used forthe binder in the light absorption part 23′ of the optical functionlayer. Acrylic beads containing carbon black was included in the binderso that the content thereof was 25 mass % on the basis of the whole ofthe composition constituting the light absorption part. The crosssection of the light absorption part 23′ was a trapezoid of 11 μm inupper base, 15 μm in lower base and 150 μm in height.

According to this, the cross-sectional area of the light transmissionpart was 79.7% of the total cross-sectional area of one adjacent lighttransmission part and light absorption part on a cross section of theoptical function layer in the layer thickness direction.

One leg part of the light transmission part 22′ (one leg part of thelight absorption part) was parallel to the thickness direction of theoptical function layer (parallel to the normal line direction of thelight input surface of the optical function layer).

The linking part of the optical function layer was 25 μm in thickness(Tk in FIG. 3).

DBEF-D2-280 manufactured by 3M Company was used for the reflectivepolarizing plate.

The layer having micro-roughness was formed with a metal mold having amicro-roughness surface. Micro-roughness was adjusted so as to be withina range of 0.01 μm and 0.50 μm in Ra75 in JIS 13 0601-2001. Here,surface roughness was measured with Surface Texture Measuring InstrumentSURFCOM (Model E-RM-S18B manufactured by TOKYO SEIMITSU CO., LTD.).

(No. 22)

In No. 22, the shapes of the light transmission parts and the lightabsorption parts were changed from No. 21 as shown in FIG. 18. Otherdetails were the same as No. 21.

According to this, the cross-sectional area of the light transmissionpart was 80.2% of the total cross-sectional area of one adjacent lighttransmission part and light absorption part on a cross section of theoptical function layer in the layer thickness direction.

(No. 23)

In No. 23, the shapes of the light transmission parts and the lightabsorption parts were changed from No. 21 as shown in FIG. 19. Otherdetails were the same as No. 21.

According to this, the cross-sectional area of the light transmissionpart was 79.1% of the total cross-sectional area of one adjacent lighttransmission part and light absorption part on a cross section of theoptical function layer in the layer thickness direction.

(Nos. 24 and 25)

In Nos. 24 and 25, the shapes of the light transmission parts and thelight absorption parts were changed from No. 21 as shown in FIG. 20.Other details were the same as No. 21.

According to this, the cross-sectional area of the light transmissionpart was 82.1% of the total cross-sectional area of one adjacent lighttransmission part and light absorption part on a cross section of theoptical function layer in the layer thickness direction.

A liquid crystal display of 6.5-inch (LQ65T5GG03 manufactured by SharpCorporation) was equipped with each of the laminates as the above, to bea liquid crystal display. More specifically, an optical sheet wasarranged on the light output surface side of a surface light sourcedevice that consisted of a light guide plate on a side surface of whicha light emission source was arranged, a prism sheet, a light diffusionfilm and a reflective polarizing plate; and a liquid crystal panel wasarranged on the light output surface side of the optical sheet.

In this test, as well as Test B, with reference to FIG. 21A (lightoutput side) and FIG. 21B (light input side), irradiation light (lightsource D65) inclining at 45° from the normal line of the optical sheet(optical function layer) was irradiated to the optical sheet in adirection of aligning the light transmission parts and the lightabsorbing parts alternately, to obtain the optical diffuse reflectanceon the light output and input sides. The results are shown in Table 3.

It is noted that one leg part of the trapezoidal cross section of thelight absorbing part 23′ which was parallel to the thickness directionwas arranged so as to be directed toward the irradiation light in Nos.21 to 24, and so as to be directed opposite thereto in No. 25.

TABLE 3 Optical Optical diffuse diffuse reflectance reflectance on onlight light Light output input blocking Interference side (%) side (%)effect fringe scintillation No. 21 2.0 9.8 x ∘ ∘ No. 22 2.1 10.7 x ∘ ∘No. 23 2.2 8.2 ∘ ∘ ∘ No. 24 2.0 9.4 ∘ ∘ ∘ No. 25 2.0 9.7 ∘ ∘ ∘

As is seen from the results in Table 3, it is found that in the laminatewhere the reflective polarizing plate is arranged, more than 9.7% of theoptical diffuse reflectance on the light input side raises a problem ina light blocking effect.

REFERENCE SIGNS LIST

1 image display device

5 image source unit

10 image source

11 surface light source device

12 liquid crystal panel

20 optical sheet

21 optical function layer

22 light transmission part

23 light absorption part

25 substrate layer

What is claimed is:
 1. A laminate having a plurality of layers, thelaminate comprising: a substrate layer; and an optical function layerthat is layered on one surface of the substrate layer, and has aplurality of light transmission parts which are arranged in a row alonga surface of the substrate layer so as to be light-transmissive, andlight absorption parts in a row, each of which is arranged betweenadjacent ones of the light transmission parts so as to belight-absorptive, wherein on a cross section of the optical functionlayer in a layer thickness direction, a cross-sectional area of one ofthe light transmission parts to a total cross-sectional area of one ofthe light transmission parts and one of the light absorption parts whichare adjacent to each other is 78.2% to 88.5%, and when irradiation lightinclining at 45° from a normal line of the optical function layer isirradiated in a direction of alternately aligning the light transmissionparts and the light absorbing parts of the optical function layer, andomnidirectional light when 45° specular reflected light is excluded fromreflected light of this irradiation light is defined as an opticaldiffuse reflectance, an optical diffuse reflectance on a light outputsurface side of the laminate is 1.9% to 3.5%.
 2. The laminate accordingto claim 1, wherein an optical diffuse reflectance on a light inputsurface side of the laminate is 2.5% to 5.0%.
 3. A laminate having aplurality of layers, the laminate comprising: a substrate layer; anoptical function layer that is layered on one surface of the substratelayer, and has a plurality of light transmission parts which arearranged in a row along a surface of the substrate layer so as to belight-transmissive, and light absorption parts in a row, each of whichis arranged between adjacent ones of the light transmission parts so asto be light-absorptive; and a reflective polarizing plate that isarranged on the optical function layer on a side opposite to thesubstrate layer, wherein on a cross section of the optical functionlayer in a layer thickness direction, a cross-sectional area of one ofthe light transmission parts to a total cross-sectional area of one ofthe light transmission parts and one of the light absorption parts whichare adjacent to each other is 78.2% to 88.5%, and when irradiation lightinclining at 45° from a normal line of the optical function layer isirradiated in a direction of alternately aligning the light transmissionparts and the light absorbing parts of the optical function layer, andomnidirectional light when 45° specular reflected light is excluded fromreflected light of this irradiation light is defined as an opticaldiffuse reflectance, an optical diffuse reflectance on a light inputsurface side of the laminate is 8.2% to 9.7%.
 4. The laminate accordingto claim 1, wherein a cross section of each of the light transmissionparts in the layer thickness direction is a trapezoid.
 5. The laminateaccording to claim 3, wherein a cross section of each of the lighttransmission parts in the layer thickness direction is a trapezoid. 6.An image source unit comprising a liquid crystal panel that is arrangedon a light output side of the laminate according to claim
 1. 7. An imagesource unit comprising a liquid crystal panel that is arranged on alight output side of the laminate according to claim
 3. 8. An imagedisplay device comprising: a housing; and the image source unitaccording to claim 6 which is arranged inside the housing.
 9. An imagedisplay device comprising: a housing; and the image source unitaccording to claim 7 which is arranged inside the housing.